Heating and cooling technologies

ABSTRACT

A heating and cooling device is disclosed comprising at least one integral low voltage heating and cooling source and an efficient flexible heat distribution means having a thermal conductivity of from 375 to 4000 W/mK for distributing the heat and cool across a surface. Further aspects include thermal interface compounds to provide full thermal contact as well as the use of a phase change material to provide a long lasting heating and/or cooling effect without the use of external electrical input. Preferred applications include automotive and furniture seating heating and cooling, along with outdoor garments having distributed heating and cooling effects.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority with the benefit under 35 U.S.C. 119(e) of U.S. Provisional Application No. 62/080,072 filed 14 Nov. 2014.

THE NAMES OF THE PARTIES TO A JOINT RESEARCH AGREEMENT

Not Applicable

INCORPORATION-BY-REFERENCE OF MATERIAL SUBMITTED ON A COMPACT DISC OR AS A TEXT FILE VIA THE OFFICE ELECTRONIC FILING SYSTEM (EFS WEB)

Not Applicable

STATEMENT REGARDING PRIOR DISCLOSURES BY THE INVENTOR OR A JOINT INVENTOR

Not Applicable

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention relates to heated and cooled assemblies for use in OEM and aftermarket heaters/coolers, methods of manufacturing same, and methods of using same. More particularly, the invention relates to conductive heat transfer systems for heating and cooling automotive seats, medical containers, office furniture of all types, food warmers, as well as articles of clothing.

2. Description of the Prior Art

Conventional heating and cooling systems for vehicle seats, furniture seats, medical containers, food warmers and articles of clothing are well known in the art, including one of the most common types of forced air heating and cooling systems that includes a forced air heater and/or cooler within an automobile seat, seat assembly or articles of clothing. Conventional heated articles have included inefficient electric resistance heating mechanisms, among others. Other utilized methods of warming include chemical reaction type systems which may be efficient, but they require a new expenditure after each activation.

Practitioners of those forced air heating and cooling system inventions have become aware of certain issues which are presented by those prior art inventions. One particular problem that has plagued car manufacturers and consumers has been that those systems utilize a great deal of energy due to the inefficiency associated with heat transfer using air as the heat transfer medium. There are other complexities which give rise to interior space concerns along with these energy consumption issues.

Heated articles of clothing, predominantly for motorcycle enthusiasts and outdoorsmen, have utilized electrical resistance wires placed throughout the clothing, much like an old fashioned electric blanket. Typically, motorcycle jackets that used the electrical wires needed to be plugged into the motorcycle to continuously feed electricity to the device.

As anyone knows who has recently purchased a vehicle, heated seats are very popular. Although heated seats may be used in a multitude of applications, I will be focusing on the automobile, as that represents the largest sales volume of heated/cooled seats which are purchased by the public. Clearly, mechanisms for heating and cooling seats may be useful for many other applications, more fully described hereinbelow.

Heating and cooling of automobile seats are desirable features that are widely adopted by automobile buyers, although there are improvements to be made on the existing systems. Updating these technologies in order to utilize less electricity, new materials and technologies help to transfer heating and cooling, hopefully minimizing moisture build up, which is advantageous for any applications in the seating industry.

The seating industry has been looking for both a one-directional and a bi-directional heat transfer material that has a high rate of heating and/or cooling. Furthermore, consistent heating and cooling over an entire heating surface while consuming a low power amount will be welcomed by the industry.

The prior art usually includes a forced convection heating system with an air distribution model dependent on air flow. As an occupant on the seat increases in weight, the quality of air flow decreases. In these cases, there is a heat sink resistance that is undesirable. In the conventionally available heated seat technologies, including the microthermal module, a Peltier circuit was used in conjunction with a heat exchanger to provide heated or cooled air that exits to the seat cushion. Issues arise due to the air distribution method which may include a first top layer of perforated leather, then a distribution layer atop conventional scrim material, followed by an underlying cushioning by a channel molded in foam. Heating and cooling has been shown to be inefficient and requires a fair amount of “real estate” or spaces for airflow passages. Although this accepted conventional standard has a relatively low cost, it is ineffective when considering the amount of energy utilized. Further moisture build up is a concern with prior art methods.

During operation, of course, it is foreseeable that people driving those vehicles may experience spills of liquids, such as sodas and coffees, from fast food restaurants, being imbibed in the vehicle are bound to happen. These spilled fluids can penetrate the seat fabric and enter into the interior of the seat causing mold growth, foul odors and bacterial growth.

Another desire of the industry is to monitor the thermal status of the seat occupant without added sensors that add complexity and expense.

In addition, another common desire of seating manufacturers is to have a seat that would store or release thermal energy for use during periods when the vehicle is not running to improve comfort for the seat occupant upon entering a vehicle and being able to maintain the thermal storage capability for longer periods.

It would therefore be desirable to the vehicle seating industry if there was provided a new alternative technology with an improved conductive heat transfer that could heat and/or cool a seat or seat assembly, along with a method of making the seats, or a method of using them for heating and cooling seats. It would be advantageous for the industry to review such a new technology. Certain technical benefits can be realized by the utilization of a conductive heat transfer system utilizing thermoelectric devices.

SUMMARY OF THE INVENTION

In accordance with the above-noted desires of the industry, the present invention provides various aspects, including a conductive heat transfer model, a method of making same, a method of controlling same and various methods of using them for heating and cooling seats. This includes a heating and cooling device, preferably a new and improved thermoelectric module adhered to and in conjunction with at least one layer of a thermally conductive material for distributing the heat or coolness throughout more of the surface area. This overcomes many of the aforementioned problems with the prior art because energy consumption can be minimized, while heating and cooling distribution is maximized.

By using optional incorporation of phase change material schemes, the problems of an inability to be directly thermally charged in the seat assembly itself, along with issues arising from a lack of methods to extend their thermal capability over a longer time are alleviated.

Improvements on existing systems may also include sensing technologies that may provide an information feedback loop, along with new materials and new thermoelectric technologies to improve the seat cooling and heating, without generating moisture.

BRIEF DESCRIPTION OF THE DRAWINGS

For a further understanding of the nature and advantages of the expected scope and various aspects of the present invention, reference shall be made to the following detailed description, and when taken in conjunction with the accompanying drawings, in which like parts are given the same reference numerals, and wherein:

FIG. 1 shows the simplest aspect of the present invention with a thermoelectric module incorporated into a thermally conductive heat transfer pad to be incorporated into a seat, a seat assembly or as an aftermarket configuration;

FIG. 2 illustrates a perspective environmental view of the present invention;

FIG. 3. is a side elevational view of a second aspect made in accordance with the present invention;

FIG. 4 is a side elevational view of another aspect of the present invention;

FIG. 5 is a side elevational view of yet another aspect of the present invention;

FIG. 6 is yet another aspect of the side elevational view;

FIG. 7 is a perspective view of the fan aspect of the present invention;

FIG. 8 is a top plan view of the multi-layer aspect;

FIG. 9 is a cutaway view of still another aspect of the seat assembly utilizing the present invention;

FIG. 10 is an environmental view of an vehicle aspect of the invention, including use in a chair with a recharger;

FIGS. 11A and 11B are top plan views of a seat assembly with graphene strips;

FIG. 12 is a perspective view of a heat transfer block and heat sink assembly;

FIG. 13 is a side cutaway view of the assemblies of FIG. 12;

FIG. 14 is a back view of a heated garment;

FIG. 15 is a perspective view of thermal box;

FIG. 16 is a flow chart of the Internet of Things application for heating; and

FIGS. 17A-17E show variations of a sheeted thermal conductive material.

Although the invention will be described by way of examples hereinbelow for specific aspects having certain features, it must also be realized that minor modifications that do not require undo experimentation on the part of the practitioner are covered within the scope and breadth of this invention. Additional advantages and other novel features of the present invention will be set forth in the description that follows and in particular will be apparent to those skilled in the art upon examination or may be learned within the practice of the invention. Therefore, the invention is capable of many other different aspects and its details are capable of modifications of various aspects which will be obvious to those of ordinary skill in the art all without departing from the spirit of the present invention. Accordingly, the rest of the description will be regarded as illustrative rather than restrictive.

DETAILED DESCRIPTION OF THE INVENTION

In order to provide the above referenced advantages to the industry, the present invention proposes a novel design using a unique combination of elements. In its simplest aspect of the present invention of a heated and/or cooled seat, garment or thermally controlled box, an integral heating and cooling device, preferably a thermoelectric device, shall be bonded to a flexible thermally conductive material for dissipating the temperature difference across an area. Basically, the thermoelectric module will act as a heat/cool source, while the thermally conductive material will distribute the heat/cool over a larger surface area.

As such, thermoelectric modules may be used as the integral source of heating and/or cooling, and when these thermoelectric modules come in thermal contact with the thermally conductive material, the heated or cooled temperature effect is spread out over a greater surface area due to thermal conduction. In order to accomplish a temperature gradient differential to heat or cool a seat, it may be preferable to utilize carbon based materials such as graphite, for spreading the temperature difference out over a wider distribution area across the surface of the seat. New graphite included materials have a thermal conductivity from one to five times higher than copper, making conductive heat transfer an industrial possibility. This may be utilized for small area conductive heating and cooling, while still being strong and flexible as well as possessing high thermal conductivity. Of course, the material must be durable enough to withstand many years of people sliding in and out of the seat.

Such a superior heat transfer design system may use the recently improved thermoelectric materials, especially those made from bismuth telluride. These new materials have incremental improvements of about 2° C. These 2° C. changes of temperature can mean the difference between “almost cool” and “cool”. This will provide a new avenue for the industry to provide cooling on seats. Materials improvements in the thermoelectric device can also be used in either improved forced air systems or for the entirely new concept in the present invention. Thermoelectric devices are solid state devices, and these solid state cooling devices can be attained with the new thermoelectric alloy and crystal growing processes. Examples of the various aspects of the present invention are discussed in greater detail more fully hereinbelow, detailing various combinations of basic forms and optional components to enhance the heating and cooling aspects. These various aspects will be broken down into component based options by paragraphs hereinbelow:

I. Combination Thermoelectric Module and Thermally Conductive Materials

a. First, the Thermoelectric Module

In its most basic form, the present invention includes the use of an integral heating and cooling device, especially a thermoelectric heating and cooling device, in thermal communication with and attached to a flexible thermally conductive material in order to spread out the heat or coolness. This is especially useful underneath the seat of any seat assembly. The thermoelectric devices that are utilized may be any conventional thermoelectric device, but are preferably bismuth telluride based devices. These devices should operate efficiently from 10 to 16 VDC, as this range is compatible with automotive electrical requirements and other low-voltage applications. Preferably, the thermoelectric device utilized is a 127 couple bismuth telluride based device, some of which are commercially available from Tellurex Corporation of Traverse City, Mich.

Although it is possible that devices with a higher couple count could be used to increase efficiency, cost benefit analysis criteria are used to decide the design of the thermoelectric modules for each application and varied seat assemblies. Should the thermoelectric or other solid state devices of different chemical or mechanical makeup be developed that will improve performance or lower cost, clearly these would be able to be utilized in the present invention.

In certain aspects, the thermoelectric module could include P and N couples that are spaced further apart which would increase the size of the thermoelectric module and therefore increase the area of direct contact with the thermally conductive material described below. In this aspect, it may alleviate the need for a thermal transfer block, which also spreads the heat flow over a wider area to give a larger area of contact for the thermally conductive material. Another control for the thermoelectric module may be the use of pulse width modulation.

b. Next, the Thermally Conductive Material

The other part of the first aspect of the present invention will include a thermally conductive material that is suitable for distributing heat and cold generated by the thermoelectric module across a wider area than the surface of the thermoelectric device itself. Although there are many different thermally conductive heat transfer materials which are rugged enough to withstand seating and millions of entries and egresses in and out of a vehicle seat, the most common ones would include thermally conductive materials such as copper sheets or woven materials, thermally conductive polymers, carbon based conductive materials such as carbon fiber fabric or graphite fabrics, and including the recently available graphene nanoplatelets sheets. Since carbon based materials are strong and flexible in addition to being highly thermally conductive, they are especially suitable for the present invention.

Graphene in a single layer atomic thickness is extremely thermally conductive, i.e. from 2,000 to 4,000 Watts/meterKelvin in the X & Y axes. Practically, though, because of the lack of cross sectional area in the Z-direction, the actual heat that can be transferred is low. In other words, the thermal conductivity is very high per cross sectional area, but if the cross sectional area approaches zero, the actual heat transfer is minimal.

Therefore, usable graphene for practical applications preferably employs many layers of graphene, often in the form of platelets, nanoplatelets, nanotubes and/or nanoparticles. Though using the graphene platelets in this form reduces the thermal conductivity per cross sectional area, the overall heat transfer can be very high because the cross sectional area is relatively large due to thickness in the Z-direction. In addition, these thicker graphene materials can be easily handled especially if bonded to a thin polymer film. As the development of this material advances, the thermal conductivity will also increase, upward of the 2,000-4,000 W/mK mark, though it is not known how close it will get to the “theoretical” limit.

The examples disclosed below utilize thermally conductive materials, some with 400-600 W/mK in thermal conductivity and some with 2000-4000 W/mK. Using multi-layers of thinner 400-600 W/mK material may increase the thermal conductivity to 1,500 W/mK. Of course, thinner multi-layer approaches increase the cost, are less available and are more difficult to work with, though this is certainly a possibility. Higher thermal conductivity graphene in low cost form is becoming available for materials in the 400-2,000 W/mK or similar range.

Further, a pyrolytic graphite sheet material tested with a higher thermal conductivity of 700-800 W/mK, including material of 1,500 W/mK. Pyrolytic graphite sheet material is a suitable thermally conductive material. Pyrolytic graphite fiber cloth of a pitch based carbon fiber fabric, commercially available from Mitsubishi Plastics of Japan had a thermal conductivity of 800 W/mK. Because it was a fabric, it was great for flexibility. However, initial tests showed that the fabric weave, was not active in carrying heat in the cross weave material. For example, in this trial, the pyrolytic graphite fiber cloth was bonded to a 3″×3″ conduction plate. The strands that were linear with the heat conduction path carried heat and the cross weave material fibers, once it left the area of the conduction plate, were perpendicular to the heat flow and only communicated with the preferred heat transfer strands at circular points where the strands met. Therefore, thermal adhesives may be used to thermally connect all the fibers.

Although any thermally conductive material may be utilized with varying degrees of effectiveness, the preferred thermally conductive materials for the present invention include graphene nanoplatelet material with a thermal conductivity of from 375 W/mK to 2000-4000 W/mK depending on thickness and configuration, while commercially available pyrolytic graphite sheets with thermal conductivity of 650-1550 W/mK and pyrolytic woven graphite fibers, with a thermal conductivity of 800 W/mK is also suitable.

Preferably, the best carbon-based thermal conductivity material is sheeted materials of graphene nanoplatelets adhered to a thin plastic sheet in order to add strength. As the thermal conductivity of graphene is more than double that of copper, it is a suitable material for this application. Such graphene nanoplatelet sheets are preferably from 5 micrometers to 500 micrometers thick, and may be optionally bonded to a thin plastic sheet made of polyethylene, or any other suitable substrate in order to exhibit greater strength and resistance to ongoing stress and strain due to persons getting in and out of seats.

By utilizing carbon-based materials, heat may be transferred and distributed directly throughout the entire surface area of the conductive material, alleviating the need for air ducting and distribution, further simplifying seat construction and standardizing the design while still providing individualized climate control, thereby increasing design flexibility. In short, the present invention uses a heat transfer pad to distribute heat and cool, rather than using forced air. Standardization becomes possible because there will be minor differences whether or not a low weight passenger is sitting on the seat or someone of more substantial weight, such as happens when a substantially weighted person may crush the air ducts in conventional seats with heating and cooling capabilities.

In that regard, suitable graphene nanoplatelet materials are commercially available from many sources, including XG Sciences, of Lansing, Mich., USA, among other international distributors. Graphene nanoplatelets are suitable for the present application because this relatively new class of carbon nanoparticles exhibits multifunctional properties. The graphene nanoplatelets have a “platelet” morphology, as they have a very thin but wide aspect ratio. This unique size, shape and morphology tends to the make the particles especially effective at providing barrier properties while their pure graphitic composition gives them good electrical and thermal conductivity properties. They also can exhibit stiffness, high strength and surface hardness. Such materials may be used in a single layer, or any number of multiple layers in order to achieve the desired effect. For automotive seating, it is preferable that a single sheet is utilized, as it has a thermal conductivity of 400-500+ W/mK. As many of the grades of graphene materials are made of either nanoplatelets, nanoparticles, nanotubes or combinations thereof that are commercially available, typical surface areas which are able to dissipate heat may include from 5 to over 750 m²/g., wherein the average particle diameters can range from 5 microns to over 100 microns. These sheeted graphene nanoplatelet or graphene nanotube materials are especially useful for dissipating heat once it is placed in direct mechanical and thermal contact with the thermoelectric device described hereinabove.

Further aspects of the invention may include the use of a thermally conductive plastic sheeted material with an inclusion of intermittent bits of highly thermally conductive components, such as carbon or graphene nanoparticles, graphene nanotubes, or graphene nanoplatelets in order to improve the thermal conductivity of the thermally conductive plastic sheeted material.

II. Combination Thermoelectric Module, Thermally Conductive Material and Perforated Top

a. The Perforated Material

In addition to the above-mentioned basic thermoelectric module and thermally conductive combination, other optional aspects of the present invention may include further elements to be added to that combination. In this second aspect of the invention, the basic thermoelectric and thermally conductive combination further includes the use of a perforated material that will contact the person in the seat. The perforated material may include perforated leather, or any other suitable perforated seating material to allow air flow to the seat occupant and prevent moisture from building up due to condensation. Suitable perforated materials will allow air flow which will therefore improve seat heating and also provide improved moisture transfer.

III. Combination Thermoelectric Module, Thermally Conductive Material, and Phase Change Material

Yet another element that may be utilized with the base thermoelectric and thermally conductive combination may include phase change materials capable of storing or releasing heat during a phase transition. This may provide additional capacity in the present application. The materials that are preferably associated with this aspect of the invention include hydrated potassium bicarbonate or other phase change materials could be used that are applicable to the phase change temperature that is desired for the application. Bear in mind that a phase change material has a high heat of fusion which is capable of storing and releasing large amounts of energy. In this instance, the heat is either absorbed or released when the material changes from solid to liquid and vice versa, which makes the phase change material a latent heat storage material. For example, a sodium acetate heating pad becomes warm when it crystallizes.

Certain organic phase change materials such as paraffin and fatty acids have very high heats of fusion and are safe and non-reactive, besides being recyclable and compatible with pretty much every conventional material of construction. Although they have traditionally been flammable, certain containment processes allow use in various applications.

Of preferred interest in this application may include inorganic salt hydrates, as they are non-flammable while still exhibiting a high heat of fusion. As described above, the preferred phase change material is a hydrated potassium bicarbonate. Of course, other phase change materials may be adapted for this application, and may include the eutectics or hydroscopic materials as they can absorb heat when their water condenses or they can release water when the water evaporates. Although not an inclusive listing, suitable the phase change materials include hydrated potassium bicarbonate, sodium acetate, paraffin, fatty acids, inorganic salt hydrates, eutectics, hydroscopics, hygroscopics, and combinations thereof. This may or may not be useful in terms of controlling the moisture content in a seat when certain dew point situations are realized.

In various aspects of the present invention, this combination of the thermoelectric module, thermally conductive material, perforated seats, and/or phase change material pads within the seat, or any combination thereof may make the seat usable to provide a more efficient system than the conventional air chamber type heating and cooling seats.

Of special interest in the present invention is that in certain aspects, there is essentially no movement of air necessary, unlike the conventional systems produced with split air chamber designs and utilizing significant amount of “real estate” underneath the seat. From a packaging and manufacturing standpoint, the thermoelectric module and thermally conductive material of the present invention is much easier for packaging, shipping and for placement in a seat during manufacturing. There are very few air chamber components that need to be manufactured and installed.

Further, the various weights of the human beings sitting on the seats hamper the design of prior art seat heaters and coolers, because the air chambers become compressed when an obese person sits on the seat versus a child sitting on the seat. As one can imagine, an obese person will compress the air chambers to the point where the air can no longer even distribute. The fact that the present invention does not rely upon air movement, gives much greater leeway to seat designers as well as the operation of the seat heater and cooler.

My design alleviates much of the moisture that is involved in seats during heating and cooling, and therefore does not even need to be addressed for moisture retention or vaporization. If no air flow exists, such as when there are no perforations to allow air flow, moisture can condense when it is cold. Using my invention, with even a 2° C. differential, and especially with perforations, the moisture problem is alleviated.

IV. Combination Thermoelectric Module, Thermally Conductive Material, and Phase Change Material with Perforated Materials

Further comprising the present invention is the optional use of all these aspects including perforated top layer materials with phase change material utilized in combination with the first aspect of the present invention including thermally conductive material in order to store or release heat during a phase transition. Such a phase change material may be any substance with a high heat of fusion which, melting and solidifying at a certain temperature, is capable of storing and releasing large amounts of energy. As one may recall sodium acetate heating pads, it is realized when the sodium acetate solution crystallizes, it becomes warm. Such phase change materials' latent heat storage capabilities can be achieved through solid-solid, solid-liquid, solid-gas, and liquid-gas phase change. The preferable phase change for use in the present application is the solid-liquid change as it is most practical for use as thermal storage due to the small volume required to store the heat. Although conventional phase change materials may be organic, such as paraffin and/or fatty acids, inorganic phase change materials, such as salt hydrates, eutectic materials, which may be organic-organic, organic-inorganic, or inorganic-inorganic compounds, along with hygroscopic materials which may be advantageous due to their water absorption and release properties.

Preferably, as mentioned above, in this aspect the phase change material which can optionally be used in the present invention is hydrated potassium bicarbonate or any other phase change material which is applicable to the phase change temperature that is desired in the automotive or other seat assembly applications.

In addition, optionally, with any or all of the above-mentioned aspects, yet another element may be helpful in order to optimize the heat transfer. This element includes a thermally conductive interface which may be utilized to great advantage. Such a thermally conductive interface may be thermal grease, silver filled gels, filled waxes, or silicones. This interface will help to make full thermal contact between the components, increasing the efficiencies of each thermal communication.

Methods for making each of the above aspects include assembling each component as shown in the appended drawings, and applying a coating of thermally conductive interface between the thermoelectric module and the thermally conductive material, or the thermoelectric, the thermally conductive and the phase change material.

These benefits include, but are not limited to, the fact that all the power used in the fan can be used for ambient heat transfer via the heat sink which will improve overall performance. An ambient heat sink can be optimized for its purpose instead of fitting into the form factor required and using a portion of the air flow also for the cooling/heating of the seat occupant. This provides more freedom for thermoelectric module design, wherein the seat packaging can also be improved. Various shapes and sizes of the heating and cooling area are easily accomplished by utilizing various sizes of heat transfer materials and the thermoelectric devices. This also means that there is a reduction in designing for occupants with different weights because the thermal feedback loop can provide better control of temperature with the occupant being directly thermally coupled to the heated and cooled surface.

Looking now to the drawings, we look at FIG. 1, wherein the seat heater and cooler is generally denoted by numeral 10, and includes a rubber pad 12 and immediately thereunder and surrounding is a thermally conductive material heat transfer pad 14 which is then in turn in thermal communication with a thermal transfer block under the thermally conductive material heat transfer pad 14 and includes a thermoelectric device under and in thermal communication with a thermal transfer block, which in turn is in thermal communication with a heat sink with a fan below the heat sink. Heat transfer pad 14 may be made of any of the thermally conductive materials described hereinabove, such as graphene nanoplatelets, graphene nanotubes or the like.

FIG. 2 shows the seat heater and cooler of FIG. 1 in its environment in an automotive vehicle seat assembly, and further illustrates the seat assembly generally denoted by numeral 20, with the seat heater and cooler 24 in place in the seat as well as in the back of the seat assembly 20. A thermoelectric device 22 is shown in a cutaway portion of the seat while the thermoelectric device 24 is shown within the heat transfer pad 26 on the back of seat 20.

FIG. 3 shows in detail the thermoelectric device in combination with the various components comprised the entire heat transfer pad and seat heater and cooler. An upper thermal transfer block 30 is located on top of heat transfer pad substrate 33 which is then placed in thermal communication with a lower heat transfer block 40. Seat foam 32 acts as a support for the passenger, and holds the upper thermal transfer block 30 in place. The thermoelectric module 36 is in thermal communication with heat sink 38 for receiving air flow from a fan 35 through air flow 34 that is heated or cooled by the heat sink 38. In operation, fan 35 creates an air flow 34 from below to bring the air up into contact with the thermo sink 38 which is then in contact thermoelectric device 36 and then to lower heat transfer block 40. Substrate 33 made of a thermally conducting material helps to dissipate the heat or coolness across its surface and also is helped by thermal interface 30. Advantageously, an optional thermal interface, such as thermal grease, silver filled gels, filled waxes, silicones or pads to name a few suitable interface materials. What was used successfully in the prototypes is Arctic Silver from AI Technology Inc. of Princeton Junction, N.J., may be used between the thermal transfer blocks and the thermally conductive material to provide a void free contact for best heat transfer.

Looking next to FIG. 4, another view of the aspect shown in FIG. 3 is shown with a further cushioning aspect of seat foam 32, topped by and defined by a thermally conductive material layer 60 which is in thermal communication with heat transfer block 62 which is sitting on top of thermoelectric module 52. Seat foam 32 surrounds air chamber exit duct 58. Heat sink 54 is shown directly below and in thermal communication with thermoelectric module 52. Fan 56 is shown in its box configuration bringing air up into the heat sink area 54 for heat exchange and also exhausting any air through air chamber exit duct 58. Seat foam 32 is located between air chamber 58 and thermally conductive material 60. All of this is meant to heat up or cool down the conductive heat transfer material 60, which is preferably made of a highly dissipative carbon based material, such as the graphene nanoplatelet material described in detail hereinabove.

FIG. 5 shows yet another aspect of the present invention utilizing a fan, air chambers, and the combination of a thermoelectric module, thermally conductive material, a perforated seat cover, and a phase change material as described above. The seat heater and cooler generally denoted by the numeral 70, and includes the flexible thermally conductive material 72 having perforations 74 therein. The perforations allow air flow to help to minimize the trapping of moisture, which alleviates the clammy feeling if the dew point is too low. Underneath the flexible thermally conductive material 72, a phase change material 76 is used to provide a storage of heat and cool. The phase change material 76 is in contact with the thermally conductive material 72 which is in thermal communication with thermal interface 78 which is in direct thermal communication with the heat transfer block 80, which in turn is in thermal communication with the thermoelectric module 82 underneath. As in the other aspects, the thermoelectric module 82 is located in thermal communication with heat sink 84 which is heated and cooled by air coming through fan 86. Fan 86 moves the air through air passages 88 in order to put moving air in contact with the seat occupant primarily to reduce the chance of moisture formation on the seat surface and will exchange some heat with the phase change material and the thermally conductive material pad as it moves through the perforations though the main heat transfer mechanism to the occupant is via the thermally conductive material and then via the seat covering material (leather or other) that is in direct contact with the occupant. Fan 86 distributes the air through the heat sink 84, transferring heat to or from the heat sink 84, depending on the direction of the electrical DC current flow direction in the thermoelectric device and whether the seat occupant is to be heated or cooled, which is then exhausted into the ambient environment through air flow chamber 90, acting as an exit duct.

Phase change materials store or release heat during a phase transition. The materials presently associated with this invention include hydrated potassium bicarbonate. Other suitable phase change materials may be applicable to the phase change temperature that is desired. Phase change materials are used only in certain aspects of this invention. They provide short-term cooling or heating to a seat occupant, for example when the stops to shop for an hour and they would want to come out to a hot car that has a pre-cooled seat. Its performance can be engineered such that a thin insulating layer of material can be placed between the thermally conductive material to allow most of the heating or cooling provided by the thermoelectric device to act upon the leather or cloth seat covering and the seat occupant, while allowing a level of thermal leakage that either heats or cools the phase change material. When the car is in the rest position, such as in the case of someone shopping or at a doctor's appointment, the phase change material can release or absorb heat slowly as the thin insulating layer retards a high level of heat transfer. How this layer, or if there is a layer at all, is engineered is dependent upon the desired thermal requirements.

FIG. 6 is yet another aspect of the present invention utilizing the perforated seat in conjunction with the thermoelectric module and the thermally conductive material pad for distributing heat or cool to the passenger of the seat. This aspect is generally denoted by numeral 100, and includes an air flow 102 coming into the fan 104. Fan 104 distributes the air through the heat sink 106, transferring heat to or from the heat sink 106, depending on the direction of the electrical DC current flow direction in the thermoelectric module and whether the seat occupant is to be heated or cooled, which is then exhausted into the ambient environment through air passage 120. Thermal interface 112 is in communication with heat transfer block 114 and thermoelectric module 116. The fan 104 also moves air through air passages 124 and up through perforated material 110 to provide air movement to the passenger on top of the seat assembly 100. Seat foam 108 surrounds air chamber 120 for circulating air.

FIG. 7 shows another aspect of the present invention and is generally denoted by numeral 130 in which air flow 132 enters into fan 134 which distributes air through an air splitting chamber 136. This low aspect ratio air moving design 130 also includes a thermoelectric module 142 which is in thermal communication with the heat transfer block 144. As the air transfers through air splitting chamber 136, it is directed through the seat 138 by ventilation there through, while exhaust air from the heat sink is exited through passage 140.

Looking next to FIG. 8, there is shown a two layer carbon based thermally conductive material pad generally denoted by numeral 150 and including a thermally conductive plate 152 that is in thermal communication with the underside of the thermally conductive base material 154. Slits 158 in the bottom layer of thermally conductive material 154 remains in thermal communication with each of the various panels created by the slits by a top thermally conductive ring 156 so that the break caused by the splits in the thermally conductive base material remain in thermal communication with one another. This configuration of thermally conductive materials to fabricate the thermally conductive pad allows for extra flexibility and robustness for application where large downward deflections in the seat are common while maintaining overall high thermal performance. For example, if a bony kneed occupant kneels on the seat, exerting a great deal of downward force, their knee will not create any problems with the material.

FIG. 9 shows a cutaway view of yet another aspect of the present invention of a seat heater and cooler with an extended thermal lifetime, which is generally denoted by numeral 160, including the base elements of a thermoelectric module 168 in thermal communication with a thermally conductive material 162 in combination with a phase change material 163 to extend the life of the heating and/or cooling aspect of the phase change material 163. Preferably, an optional layer of thermal interface 164, such as a thermal grease or any other suitable interface material as described hereinabove, may be used to create a better connection for thermal communication. A heat transfer block 166 may also be utilized in a similar fashion as the aspects described above, in order to distribute the heat or coolness across a broader area. Thermoelectric module 168 would preferably be a similar thermoelectric module as the ones described above, which would be the heat or coolness source that is dissipated by heat transfer block 166. As shown in FIG. 9, a heat sink 170 collects the proper heat or coolness as it passes through from fan 176. Not shown are heat or coolness collecting fins in heat sink 170, as this angle shows the side of the last fin. An exit duct 174 is used for egress of air moving through the seat heater and cooling assembly 160. Seat foam 172 surrounds the exit ducts 174, fan 176, and heat sink 170. Fan 176 is shown in a side elevational view, so it appears as a fan underneath heat sink 170, which urges an air flow through exit duct 174.

Looking back at FIG. 9, it should be noted that FIG. 9 shows a seat heater and cooler assembly that incorporates a phase change material, without any air flow directly to the occupant, such as with the aspects above that included a perforated air flow seat design. Phase change materials can extend the life of a heated and cooled device without the need for electricity, because phase change materials utilize chemical reactions that are either exothermic reactions, which give off heat, or they may utilize an endothermic reaction, which absorbs energy, thereby cooling. Upon activation, the phase change material, preferably potassium bicarbonate in this aspect, will heat up or cool down, whichever is desired, and will keep that temperature for an extended period of time. Since phase change material is perfectly reversible, without any hysteresis, it can be used and reused many times over to provide the desired effect. Further, it can be used in combination with the thermoelectric device and the effect of the phase change material can be distributed over a larger area by the use of the thermally conductive material.

FIG. 10 shows yet a further aspect of the present invention, for use in, for example, an office chair or any other non-automotive application or in an automotive application where running electrical wiring is not desirable, a rechargeable system is disclosed and is generally denoted by numeral 260, including an office chair 262 having a heated and cooled seat 266. At the bottom of the office chair is a magnetic resonance receiver 264 which can be moved in close proximity to the embedded magnetic resonance transmitter 268 within floor mat 270. In operation, the magnetic resonance receiver 264 is placed over the embedded magnetic resonance transmitter 268, such that wireless recharging or powering of the heated and cooled seat 266 can be achieved. Power from the floor mat is transmitted by embedded magnetic resonance transmitter 268 wirelessly to the magnetic resonance receiver 264 when it is in proper location, thereby providing power to the heated and cooled seat 266 in the office chair.

In yet one more aspect, the present invention can include a superhydrophobic aspect for addressing moisture issues. The superhydrophobic material is envisioned on the top surface of the seat top material which would optionally be the uppermost layer in any of the above aspects. In that regard, and for some of the aspects hereinabove, a possibility exists for water to condense onto the cool surface of the heated and cooled seat surface. Air flow through a perforated seat and/or air chambers or ducts will move air, thereby effecting a remedy by evaporating the condensed moisture. This circulating air aspect was also noted above, in the aspect with air moving through perforations in the thermally conductive material. In this aspect, the use of a superhydrophobic surface in incorporated in the seat covering, whether it be leather or cloth. The superhydrophobic surface propels water droplets from the surface of the seat by self-propelled jumping condensate powered by surface energy upon coalescence of the condensed water phase. This aspect can keep the seat surface dry when water condensate begins to form on the seat surface. Such a superhydrophobic material may be commercially available as “Never Wet”, from Rust-Oleum of Vernon Hills, Ill., or a superhydrophobic material available from Lotus Leaf Coatings, Inc., of Albuquerque, N.M.

Furthermore, in certain aspects, the thermally conductive layer can act as an active thermal gate for heat transfer to and from the phase change material layer. For example, if during previous vehicle operation, the phase change material layer was cooled, and now the vehicle is parked on a hot sunny day and, under normal circumstances, the phase change material would then begin warming up due to heat transfer from the car seat outer covering, whether it be leather or cloth. In this example, heat would move from the leather or cloth outer car seat covering to the thermally conductive material layer to either directly to the phase change material, or in an alternate aspect, an intermediate variable insulating layer through to the phase change material layer. This variable insulating layer may be a layer of insulating or partially insulating material that separates the phase change material from the thermally conductive material. Determining the insulating value of such a variable insulating material will be dependent upon the expected conditions of use. If the heat pumping product is to be slowly imparted upon the phase change material, a more insulating layer would be chosen. In this instance this would mean that the phase change material would either take-in or give-off heat also at a slow rate, depending on whether the seat is in heating mode or cooling mode. This means that the seat surface temperature thermal response to the heat pumping of the thermoelectric system would be little affected. If one desired a more rapid thermal response of the seat surface temperature by the heat pumping portion of the system, a higher insulating layer would be more suitable and appropriate. Consequently, if an application requires quicker charging or discharging of the phase change material, a less insulating layer would be used.

On the other hand, if the thermally conductive material layer is to be activated in the cooling mode, via the thermoelectric device, during the period of time the vehicle is parked, thermal energy from the seat covering would be transferred to the thermally conductive material layer and pumped out of the immediate area, blocking heat transfer to the phase change material layer further extends the thermal storage time of the phase change material during times when the vehicle is non-operational times. As in the cooling mode noted above, the same type of operation can be effected in the heating mode during cold weather by using the thermoelectric device to pump heat into the thermally conductive material, thereby blocking heat from escaping the phase change material. The level of heat pumping acting as a thermal block to reduce heat transfer to the phase change material layer may be regulated to meet the requirements desired by the vehicle occupant in accordance with the vehicle manufacturer's specifications.

As one can imagine, a higher heat pumping level will require more electrical energy from the vehicle. Consequently, a higher amount of electrical energy is needed in the long haul, thereby negatively affecting the reserve power in the vehicle's battery. Time-temperature algorithms that properly match intended use with electrical energy consumption are anticipated by this invention. For example, by inputting commonly experienced vehicle cabin temperatures with pre-selected times or learned occupant usage patterns along with vehicle battery conditions, the amount of heat pumping and heat blocking may be easily optimized. Furthermore, it is envisioned that this control system can also simply be used as a timer, in its simplest form.

In addition, during certain aspects' operation of the seat cooling and heating method which only uses the thermally conductive material option without the phase change material layer, or the method that uses the thermally conductive material with air flow, one can use these same thermal controlling methods, materials and concepts for the parked or vehicle at rest scenario described hereinabove.

Looking next to FIG. 11A and FIG. 11B, there can be seen yet another aspect of the present invention utilizing strips of the thermally conductive material, rather than an entire sheet of material, like the one shown in FIG. 1. It appears that the less mass of the thermally conductive material used, the faster that the heat/cool is able to be disbursed. This translates into a faster response time to the passenger of the seat. Sensory response to this arrangement can vary with the individual seat occupant but what has been observed is that because smaller areas are heated and cooled, their temperature can be changed at a somewhat faster rate than when using full sheet, full seat coverage. This allows for a more dramatic response to the seat occupant and a sensory response that can seem faster. However, as one can note, a smaller area of the seat is heated or cooled. Optimization of the net covered area versus heating or cooling across the entire surface has been determined to be about 20% net covered area with strips covering up to about 50% net covered area. The thermally conductive material is in thermal communication with a thermoelectric device and acts to distribute heat and coolness across the seat.

Looking still at FIGS. 11A and 11B, seat assemblies generally denoted by numerals 300 and 316 respectively are shown attached to seat supports 310, and 318, and including thermally conductive material strips 312 and 320 in thermal communication with thermoelectric devices 314 and 322. Device 314 is shown covered with a foam block, while device 322 is shown without the foam block. FIG. 11A illustrates a foam piece that allows for near the same level of foam thickness across the seat for comfort. The graphene strips are in thermal communication with a heat transfer plate, much like the other aspects. The graphene strips emerge through the foam, just like that shown on FIG. 3. In FIG. 11B, this shows a heat transfer plate, which is in thermal communication with the graphene strips prior to the foam being put into place that will make it a more monolithic foam surface for comfort.

FIG. 11B shows an electrical wire 324 for electrical communication to a power source. Automotive seat assemblies generally use foam for comfort and support. Generally, polyurethane foam is preferred, and is well known in the art. In all automotive cooled/heated seat applications, while foam is still used for occupant comfort, it also acts as a thermal insulator to block the movement of heat from the thermally conductive material, which supplies the cooling and heating to the seat occupant, from being dissipated, un-doing its intended function. Whether the foam is common polyurethane, specially formulated polyurethane, or other polymeric material or whether it is made of another material such as cotton, synthetic fabric material, fiberglass, polyisocyanate foam, or natural batting material, the function is the same. Seating foam is commercially available through many automotive supply companies such as Johnson Controls Inc. of Michigan, Faurecia of Europe, or chemical suppliers such Dow Chemical Corporation of Midland, Mich.

FIG. 12 illustrates a perspective elevational view of an aluminum block heat transfer member generally denoted by numeral 326. An aluminum block 328 is in thermal communication with a sheet or strips of thermally conductive material 330, preferably graphene material. Aluminum block 328 sits atop thermoelectric device 332 for efficient heat transfer. A heat sink assembly 334 lies underneath the thermoelectric device 332, showing the vertically oriented heat sink fins. A fan 336 blows air across the heat sink fins and receives electrical power by electrical wire 338. Alternatively, aluminum block 328 may be replaced with a multi-layer assembly of thermally conductive strips adhered to one another as more fully described with reference to FIG. 13 below.

In this and all other aspects, preferred suitable thermally conductive flexible materials may include graphene nanoplatelet or nanotube sheets or strips, although any other suitable thermally conductive flexible material may be used. A particularly suitable thermal conductivity material used thus far in development of this concept includes the use of a graphene nanoplatelet sheet of 180 μm thick sheeted material made from a sheet of graphene nanoplatelet material bonded to a suitable substrate material, such as a thin plastic sheet, for added strength. In this aspect, the thin plastic sheet substrate may be any suitable sheeted plastic, but is preferably polyester or polyethylene, as these materials exhibit a bit of thermal impedance. A 220 μm thick sheet was also tested and found to be suitable. The thickness of the material shall be based on the area that requires cooling and heating. This determined thickness can range from 120 μm to 220 μm but other thicknesses may be used for certain applications. This material preferably has a thermal conductivity of 400-500+ W/mK. Such a suitable graphene nanoplatelet material is commercially available from XG Sciences, Inc. of Lansing Mich. Other materials have also been used include carbon fiber fabric and graphite fabric, such as some of the industrial materials purchased from several companies such as Mitsubishi Plastics of Japan.

Many possible thin sheeted substrate materials may be used onto which multiple graphene strips are glued to act as a low mass and lower weight support. Especially thin strong materials, such as carbon fiber material, a mesh of plastic or metal, or even a thin layer of fiberglass may be useful as a substrate onto which the multiple strips are adhered, forming a strong yet flexible structure. This thin sheeted substrate material being adhered to the graphene strips or sheet may have many configurations, including a solid sheet, or a partial sheet, such as one with perforations, expanded foraminous slits, or any other configuration which would expose a net free area of contact from between 4% and about 50% to provide a more direct contact with the heat transfer materials without the thermal impedance of a covering layer. Using this multi-layer strip “paper mache” configuration may be most advantageous because it will heat up faster than a solid aluminum block, such as the one disclosed above in FIG. 12, because the system would not have to push all the heat or cool out of the aluminum block first before heat or coolness would be transferred to the surface of the seat. This configuration has a much smaller mass and better heat conductivity than a solid metal block.

In this and other aspects of the present invention, the use of a heat transfer block may be desirable. A heat transfer block allows the heat transfer area of the thermoelectric device to be increased, thereby increasing the thermal contact area of the thermally conductive material used to spread the heat to the seat occupant or to capture the heat from the seat occupant. This increased area reduces the thermal resistance of the heat pumping system. A heat transfer block can be of any thermally conductive material and is commonly aluminum and can be sourced from any commercial metal supplier. Alternatively, the multiple strip configuration described above may be advantageous. In some instances, the heat transfer block may not be required with the thermoelectric device being bonded directly to the heat transfer material.

Furthermore, in these various aspects, the inclusion of a heat sink may be desirable. The heat sink may be in the form of a common finned heat sink, which allows heat to be either taken away during the cooling mode from the sink or transferred to the sink during the heating mode by the passage of air. This type of heat exchanger can also be constructed of other metals such as copper or other thermally conductive materials such as carbon, graphite, or thermally conductive plastics. Other suitable air type heat exchangers may include folded fins, micro-channel configurations, liquid, and heat pipes. Another method is to use the same or similar type of thermally conductive material that is used in the seat for thermal transfer of cooling and heating and use it for the heat sink. This uses a conductive method to transfer heat to or from a source to the heat pumping device. As an example, a thermally conductive member can be attached to the metal floor of a vehicle. Heat sinks can be purchased from many suppliers worldwide such as Aavid Thermalloy LLC distributors throughout the world.

In addition, to increase the efficiency of this heating and cooling system, a fan may be desirable. The preferred fans include both axial and radial fans. These fans are used to pass air through a heat sink and in some applications of the present invention, also pass air through the seat cover to the occupant. Depending upon the size of the seat and the cooling and heating requirements, these fans can have capacities ranging from 5 cfm to 35 cfm of airflow and are preferred to be of a brushless design and electronically commutated. For large bench seating applications in open air environments, such as in golf cars, the fan flow rate may be higher. Other air moving means may also be employed such as piezoelectric fans, diaphragm air pumps, air flow multipliers or electrostatic air movers. An axial fan desirable in some of the aspects shown in the drawings are uniquely suitable because it provides for both passing air through the heat sink and also supplies flowing air to the seat occupant via the use of pass-through cavities in the heat sink. A rotary fan will split the flow of air so that some goes through the heat sink and some goes to the seat occupant.

FIG. 13 illustrates an alternative aspect 340 to the aluminum block heat transfer block of FIG. 12, and indicates the use of multiple adhered layers 342 of the thermally conductive flexible material for the heat transfer block. This aspect is much like a “paper mache” build up of material to construct a heat transfer block member that thermally connects the thermoelectric device 348 to the graphene strips 342 distributing heat and coolness through the seat assembly, as shown above in FIGS. 11A and 11B. Preferably, in this aspect of the invention, multiple adhered layers 342 of nanoplatelet graphene sheets or strips are adhered together to form a somewhat flexible multi-layer thermal transfer block replacement for the previously described solid aluminum heat transfer block. By substituting this “paper mache” version of the graphene strips, a lower mass heat transfer member is achieved, while retaining strength and flexibility. This aspect was designed to provide more robustness and flexibility of the material in the event that more weight is pressed down onto the seat, such as when an obese person sits down or especially if he puts all his weight on his knee, thereby compounding the downward force at a pin point. The flexibility afforded by this structure was helpful. This multi-layer concept was tested and showed an improvement in the overall robustness of the conductive member of the invention, while maintaining good heat transfer properties.

Referring again to FIG. 13, it can be seen that the multi-layer strips could either be butt jointed to the top of the thermoelectric device 348 or the C-shaped configuration shown in FIG. 13 may be employed to increase the surface area contacting the thermoelectric device, or in another aspect, a thermal transfer plate 346 on top of the thermoelectric device348 may be utilized. Heat sink 350 receives air from fan 352 and moves the air across the surface of the thermoelectric device 348. Graphene sheet 344 is secured atop the heat transfer plat 346 which transfer temperature to graphene sheet 344 to distribute heat and/or coolness. Although not shown explicitly, the base layer of the bottom of the C-shaped thermally conductive material was tested in two different configurations, i.e. in direct bonded contact with the heat transfer block or being directly bonded to the thermoelectric module itself, depending on the design. The bottom of the C-shaped configuration is a multi-layer structure bonded with a flexible adhesive heat transfer material. Suitable adhesives for any of the aspects of the present invention may include any thermally conductive interface, including thermal greases, silver filled gels, filled waxes, silicones, pads or any combination thereof.

Preferably the thermally conductive adhesive is a reworkable, aluminum nitride filled, electrically insulating and thermally conductive paste type adhesive, although any suitable adhesive may be used. In this example, such a suitable flexible epoxy adhesive may include Prima-Bond® or Arctic Silver®, adhesives, both commercially available from AI Technology, Inc. of Princeton, N.J.

In the preferred aspect, the base layer was slit to allow for more deformation during use. Greater deformation is needed in instances such as when an obese person puts his knee on a car seat and puts a significant portion of his body weight on top of a relatively small area of the seat, without crinkling the multi-layer. The second layer elastically and physically holds the slit sections in place and provides for heat transfer between the slit sections so as to maximize heat transfer between the sections and prevent any hot or cool sections relative to the other sections (temperature uniformity).

For all aspects of the present invention, suitable thermoelectric cooling/heating devices may include any commercially available thermoelectric device. The preferred thermoelectric devices are 127 couple bismuth telluride based devices, as they operate effectively at 10-16 VDC, which is compatible with automotive electrical requirements and other low voltage applications. It is also possible that devices with higher couple counts will be used to increase efficiency. Such suitable thermoelectric devices can be purchased from several manufacturers such as Marlow Industries of Dallas, Tex.

Yet another aspect of my invention includes apparatus and methods for the vehicle operator to have the capability to communicate to the vehicle that they would like the car seat to be pre-cooled or pre-heated before they enter the vehicle. The thermal seat portion of the invention can be activated by wireless communication from the operator via a mobile communication device or key fob.

Furthermore, in still another aspect of the present invention, the thermoelectric module that is a part of this invention can act as a sensor. In prior art air-only based seat heating and cooling systems, the thermoelectric module is thermally separated from the seat surface and the seat occupant. However, in my invention, the occupant is in thermal contact with the seat cover, which is in contact with the thermally conductive material which is in contact with the thermoelectric device. Thermoelectric devices, while being able to provide heat pumping bi-directionally, can also produce electrical energy via the Seebeck effect when there is a temperature difference between the two planar sides of the device. Therefore, utilizing this electrical generation aspect of this invention, heat from the occupant can be used to generate electrical energy that can be directly related to the temperature of the occupant and become a temperature sensor. The temperature information can be used to help control the temperature of the seat occupant and automatically aid in turning on or off or modulating the heat supplied to the seat occupant or the heat removed from the seat occupant providing optimal comfort.

FIG. 14 illustrates yet another aspect of the present invention with a thermally controlled garment generally denoted by the numeral 360. Jacket 362 includes thermal controls on its back to keep the occupant warm and/or cool in accordance with the present invention. Heat distribution sheets 364 surround at least a portion of the inner layer of jacket 362, and these heat distribution sheets are in thermal communication with thermoelectric device 370 and heat sink 366 through heat transfer plate 368. As with other aspects of the present invention, the thermoelectric device and the heat distribution sheets are in accordance with the descriptions hereinabove. Thermoelectric device 370 may be used to either heat or cool the garment, providing comfort and temperature controls for the wearer of the garment. Thermoelectric device 370 can be powered either by a battery or can be plugged into any outlet, such as one on a motorcycle, a snowmobile, or a boat.

Looking again at FIG. 14, It must be noted that such a jacket 362, or any other garment incorporating the heating and cooling technologies of the present invention, can be utilized for firemen, Coast Guard boats men, military applications and the like. In these instances, since they would be out-of-doors applications, and the garment would not be anywhere near an electrical outlet, a battery power pack would also be an advantage.

Garment 360 can exhibit gradient heating and cooling zones by insulating portions of the path for the thermal distribution, thereby intensifying the hot/cold at a particular location distant from the thermoelectric device. This is an attribute that is unachievable with electrical wiring systems.

Looking next to FIG. 15, a refrigerator or heater box generally denoted by numeral 380 includes a box container 382 with a heat distribution sheet 384 surrounding the cavity inside the box 382. Thermoelectric device 386 is in thermal communication with heat distribution sheets 384, providing heat and or coolness to the contents of the box. This is a great advantage over the prior art because previously, uncontained liquids such as melted ice liquids could not be included in the cooling boxes as they might harm the fan. In the present aspect of this invention, water in the box does not matter. Again, this box can either be activated electrically through an electrical output through a wire or through a battery pack. In addition, the exterior of the box can be constructed such that the outer skin is of graphene material and provides the heat sinking that may be normally supplied by a heat sink and fan.

In all aspects, if the device is only to be used in the cooling mode, the heat sink could be comprised of a heat pipe to reject the heat from the hot side of the thermoelectric device, providing a greater cooling efficiency. Likewise, a thermally conductive material, like graphene, could be use on both sides of the thermoelectric device. The thermally conductive material on the hot side could be conductively attached to a heat dissipation member, such as the auto body cockpit floor of an automobile, to dissipate heat without the use of a fan or other mechanical heat dissipation device.

Referring next to FIG. 16, a new thermal control technology via the Internet of Things (IoT) is made possible with the present invention. Office chair 390 is in electrical communication with a magnetic resonance or inductive recharging pad 392. Especially in the office chair application, as previously disclosed in the description of FIG. 10, controlling operation of the cooling and heating functions as they relate to the temperature in a building and providing information on the seat occupant and use of the chair is accomplished by integrating the seat cooling and heating system with control technology. As already noted above, the cooled and heated seat system can act as a sensor, providing a wireless signal to a smart thermostat 394, which is in communication with a computer that controls the temperature settings of HVAC system 396.

When a person sits in seat 390, the thermal energy from the person is transmitted via the heat distributing graphene to the thermoelectric device. The transmitted thermal energy creates a temperature differential between the two sides of the thermoelectric device and electrical energy is then produced. This electrical energy can power a transmitter that can indicate that there is someone sitting in seat 390. When connected wirelessly to a smart room thermostat 394, thermostat 394 and building HVAC system 396 can know that a person is sitting in their seat and, sensing the temperature of the building space and the normal desired seat temperature of the seat occupant, transmits to the seat the proper set temperature desired by the occupant, initiating either cooling or heating of the seat via the seat cooling/heating system.

The thermal control technology can also function in such a way that the seat transmits a signal to smart room thermostat 394 that the seat is being occupied and is cooling or heating to a certain temperature and smart room thermostat 394 communicates with the building's HVAC system 396 and provides less cooling or less heating to the space because the individual in the seat is comfortable in their personal space and does not require the building to fully provide for the occupants thermal comfort.

By providing individualized comfort for the seat occupant in their seat due to operation of the cooling or heating process provided by the seat, the temperature of the conditioned space can be allowed to be either warmer or cooler than would normally be provided, reducing the energy required to maintain the conditioned space's temperature. For example, in a building where summer heat requires the cooling of the building, a person in a thermally controlled chair can maintain their personal comfort even if the building is allowed to drift up in temperature by several degrees. Not having to provide as much air conditioning saves energy.

Another aspect of the heated and cooled seat technology that is communicating with other devices by the Internet of Things (IoT) is that the building operator can know which seats are being occupied and where they are occupied and adjust the thermal control for the space accordingly. Other aspects of the building's systems can also be optimized such as lighting and security systems. In addition, via the cloud, the system can communicate seat use parameters to the seat manufacturer or building owner so as to gather information on how the seating system is being used and use this information to improve the seat user's experience.

Mobile phones can communicate to the chair with information as that the office worker will be arriving to sit in the chair soon, so the chair can be thermally preconditioned upon the seat user's arrival or to set the preferred temperature for the chair. Via a mobile device, a seat occupant can control chairs in different portions of the building if they are moving to another seat for a meeting.

In a like fashion, extensions of the technology can be utilized with the above-mentioned thermally controlled garments. By using the same thermal engine used in the seating application, the heating and cooling system can be used to control body temperature. In this application, the graphene material is positioned to wrap around the garment wearer and provide thermal control in both heating and cooling modes. Though the drawing shows a jacket as the garment, other garments can also be thermally controlled in a similar manner. Phase change material, as noted above for seating applications, can also be employed in this application.

The present invention can be used to thermally control the thermal box from above. Using the same thermal engine, the system can be used to heat and cooled insulated spaces such as a ‘cooler box.’ Present thermoelectrically heated and cooled cooler boxes, like those made by Igloo Products Corporation or Coleman International of Kansas, use air that is heated or cooled by passing box interior air through a heat sink. Therefore, liquid levels in the box must be maintained below a certain level or damage to the system can result. Ice, for example, should not be used in these coolers. When the ice melts, water can easily penetrate the fan/heatsink/thermoelectric module/wiring and cause failure. The present system wraps the thermally distributing graphene around the inside wall of the cooler box, or molded into the interior box liner, and is thermally connected to the thermoelectric system in the same way as the seat cooler/heater.

The following applications for my heating and cooling technology are envisioned for the present invention. First, there are heated and cooled seating applications for vehicles of all types, such as automobiles, farm equipment, as well as other seating applications for office furniture and the like. Although this invention is not limited to the following, some of the applications will include automotive seating, truck seating, motorcycle seating, off-road vehicle seating, golf car seating, heavy equipment seating, farm equipment seating, office chair seating, military vehicle seating, airplane seating, wheel chair seating, therapeutic blankets, therapeutic bedding, therapeutic wraps, hyperthermic cancer and other treatment beds, cooled and heated surfaces in automobiles, cooled and heated surfaces—general, cold-chain medical, food, chemical thermal storage boxes, heated and cooled garments, industrial process temperature controlled surfaces, biological incubation apparatus, digital display temperature control, thermal chromic signage and displays, thermal control of batteries, heated & cooled automotive steering wheels, led cooling plain, electronic circuit board thermal maintenance, cooled/heated large format food display and serving surfaces.

FIGS. 17A through 17E illustrate variations of devices and methods for improving thermal conductivity in the Z-axis in specific areas, especially in the area where the heat is transferred from the thermoelectric device, usually by a thermally conductive member or thermal block. It can also be directly attached to the thermoelectric device. In describing these variations on how to accomplish this, a perforated plastic or other film layer such as those described in FIGS. 17A-17E. FIG. 17 A illustrates a top or bottom view of a sheet of film layer, preferably a plastic or polyurethane layer, wherein perforations can exist on either one side or both sides, depending upon the application. If it is on both sides, as is shown in FIG. 17 see, the holes are preferably offset so as to maximize strength of the substrate film layer. However, any suitable substrate may be used besides a plastic film.

FIG. 17A generally denotes a film layer by the numeral 400, and includes a sheeted film 402 having perforations on the top 404 and shown in phantom are underneath perforations 406. FIG. 17B is a side view of the film of FIG. 17A, illustrating the relative placement of a heat transfer block 412 in contact with a thermal interface compound 414, having extruded through perforations 416. Once the thermally interfacing compound squeezes into perforations, it makes intimate thermal contact directly with the graphene 408 resulting in a higher thermal conductivity contact.

FIG. 17C illustrates a perforated film with perforations on both the top and the bottom. Plastic film 420 has perforations 422 formed therein with a sheet of graphene 424 lying there between for strength. Thermal interface compound 426 oozes between the planar surfaces and provides a complete thermal communication contact between the elements and the heat transfer block 428. Under high pressure, graphene platelets will extrude into the void areas left by the perforations in the film layer which is used for support. This results in a planar surface where the graphene material is filling the voids and the thermal interface compound just provides the interface between the planar surface and the heat transfer block.

In yet another aspect, FIG. 17D illustrates a thermal contact area by the voids in the film. In this aspect, the heat transfer compound 436 squeezes into the void areas in the film layer, showing where graphene layer 432 is intermediate between the film layer 430 on top of heat transfer block 434.

In yet another variation of the film layer, FIG. 17E shows another aspect of the present invention wherein a needle plate is disclosed to make better thermal contact. In FIG. 17E, film 440 surrounds a sheet of graphene 448. Atop thermoelectric device 444 is heat transfer block 442 which includes thermally conductive needle-like members which extend up through thermal transfer compound 446 to make contact with graphene layer 448. By the inclusion of needles on the heat transfer plate 442, greater surface area is incorporated and therefore better heat transfer can be obtained. The heat transfer needles may penetrate the film layer into the thermally conductive material. The heat transfer block with its needles are preferably made of a highly thermally conductive material such as copper, aluminum, magnesium, pyrolytic graphite, or combinations thereof.

In this aspect, the needles penetrating the graphene take advantage of the extremely conductive X and Y axis thermal conductivity of the graphene and transfer heat into or out of the graphene in the Z axis.

In summary, numerous benefits have been described which result from employing any or all of the concepts and the features of the various specific aspects of the present invention, or those that are within the scope of the invention. The foregoing description of several preferred aspects of the invention have been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Obvious modifications or variations are possible in light of the above teachings with regards to the specific aspects. The aspect was chosen and described in order to best illustrate the principles of the invention and its practical applications to thereby enable one of ordinary skill in the art to best utilize the invention in various aspects and with various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims which are appended hereto.

INDUSTRIAL APPLICABILITY

The present invention finds utility in the seating industry as well as other applications where heating and cooling distribution may be effected efficiently. 

What is claimed is:
 1. A heating and cooling device with a sheeted thermally conductive material for heating or cooling a surface configured to contact a person, comprising: a low voltage heating and cooling source, including a thermoelectric device for generating heat or coolness; and a flexible sheeted thermally conductive material in thermal communication with said heating and cooling source for distributing heat or coolness generated by the thermoelectric device across a wider area than the surface of the thermoelectric device itself, including a sheeted thermally conductive material for distribution of heat or coolness generated by the thermoelectric device for heating or cooling the surface configured to contact the person, said distribution being across an area extending beyond and outside of the surface of the thermoelectric device itself, said flexible sheeted thermally conductive material being secured to and in thermal contact with the thermoelectric device and adapted to conductively heat or cool the surface configured to contact the person, and wherein said flexible sheeted thermally conductive material has a thermal conductivity of from 375 to 4000 W/mK for distributing the heat and coolness across the surface configured to contact the person; said flexible sheeted thermally conductive material comprising a strip of flexible sheeted graphene material that is thermally conductive for distributing the heat or coolness from the thermoelectric device across the surface configured to contact the person, wherein the flexible sheeted graphene material is configured to have air flow through the flexible sheeted graphene material to be conditioned by passing through openings in graphene of the flexible sheeted graphene material, whereby both conductive cooling or heating to the surface configured to contact the person and convective cooling or heating via moving conditioned air is provided.
 2. The heating and cooling device of claim 1, wherein said thermoelectric device is a bismuth telluride thermoelectric device.
 3. The heating and cooling device of claim 2, wherein the thermoelectric device is a 127 couple or higher count bismuth telluride based device.
 4. The heating and cooling device of claim 1, wherein said low voltage heating and cooling source is configured to operate at a voltage ranging from 10 to 16 VDC, or from a wireless power source transmitted to a magnetic resonance receiver from a magnetic resonance transmitter for wireless recharging.
 5. The heating and cooling device of claim 1, wherein the sheeted thermally conductive material includes thermally conductive materials comprising at least one of thermally conductive flexible sheeted graphene material, polymers, or carbon based conductive materials including carbon fiber fabric and graphite fabrics.
 6. The heating and cooling device of claim 1, wherein the sheeted thermally conductive material includes graphene sheets, strips and slitted thermally conductive material strips in thermal communication with each other.
 7. The heating and cooling device of claim 1, wherein the sheeted thermally conductive material comprises a layer of sheets or strips made of a graphene material comprising at least one of graphene nanoplatelets, graphene nanotubes, or graphene nanoparticles.
 8. A heating and cooling device with a sheeted thermally conductive material for distributing heat or coolness across a surface configured to contact a person, comprising: a heating and cooling source configured to heat or cool the surface configured to contact the person; a flexible sheeted thermally conductive material in thermal communication with said heating and cooling source, said flexible sheeted thermally conductive material having a thermal conductivity of from 375 to 4000 W/mK for distributing the heat or coolness generated by the heating and cooling source across a wider area than the surface of the heating and cooling source itself; and a thermally conductive interface for creating a thermal connection between the heating and cooling source and the flexible sheeted thermally conductive material, wherein the flexible sheeted thermally conductive material is configured to have air flow through the flexible sheeted thermally conductive material to be conditioned by passing through openings in the flexible sheeted thermally conductive material, whereby both conductive cooling or heating to the surface configured to contact the person and convective cooling or heating via moving conditioned air is provided.
 9. The heating and cooling device of claim 8, wherein said heating and cooling source comprises a thermoelectric device.
 10. The heating and cooling device of claim 9, wherein said thermoelectric device is a bismuth telluride thermoelectric device.
 11. The device of claim 10, wherein the thermoelectric device is a 127 or higher count couple bismuth telluride based device.
 12. The heating and cooling device of claim 8, wherein said heating and cooling source is configured to operate at a voltage ranging from 10 to 16 VDC, or from a wireless power source transmitted to a magnetic resonance receiver from an embedded magnetic resonance transmitter for wireless recharging.
 13. The heating and cooling device of claim 8, wherein the flexible sheeted thermally conductive material includes thermally conductive materials comprising at least one of thermally conductive flexible sheeted graphene materials, polymers, or carbon based conductive materials including carbon fiber fabric and graphite fabrics.
 14. The heating and cooling device of claim 8, wherein the flexible sheeted thermally conductive material includes graphene sheets, strips and slitted thermally conductive material strips in thermal communication with each other.
 15. The heating and cooling device of claim 8, wherein the flexible sheeted thermally conductive material comprises a layer of sheets or strips made of a graphene material comprising at least one of graphene nanoplatelets, graphene nanotubes, or graphene nanoparticles.
 16. The heating and cooling device of claim 8, wherein the thermally conductive interface comprises at least one of thermal greases, silver filled gels, filled waxes, silicones, or pads.
 17. The heating and cooling device of claim 8, wherein the thermally conductive interface includes a reworkable, aluminum nitride filled, electrically insulating and thermally conductive paste type epoxy adhesive.
 18. The heating and cooling device of claim 8, further comprising a thermal control technology via Internet of Things (IoT) connected wirelessly to a smart room thermostat or a building HVAC system.
 19. The heating and cooling device of claim 18, wherein the heating and cooling source comprises a thermoelectric device, the thermoelectric device configured to produce electrical energy via Seebeck effect with a temperature difference between two planar sides of the thermoelectric device, wherein a temperature sensor is configured to be powered by utilizing electrical energy produced via Seebeck effect, wherein temperature information from the temperature sensor can be related to temperature of the person used for controlling temperature of the surface configured to contact the person and aid in turning on or off or modulating heat supplied to or heat removed from the surface configured to contact the person.
 20. A heating and cooling device to heat or cool a surface configured to contact a person, comprising: a heating and cooling source configured to heat or cool the surface configured to contact the person; a flexible sheeted thermally conductive material having a thermal conductivity of from 375 to 4000 W/mK for distributing the heat and coolness across the surface configured to contact the person, said flexible sheeted thermally conductive material configured to distribute heat or coolness generated by the heating and cooling source across a wider area than the surface of the heating and cooling source itself and to spread the heat or coolness out over a wider distribution area across the surface configured to contact the person; and a phase change material for maintaining a temperature for a period of time past operation of the heating and cooling source, the phase change material in thermal communication with the flexible sheeted thermally conductive material, wherein the phase change material is configured to have air flow through the phase change material to transfer heat or cool between the air and the phase change material to then flow toward the surface configured to contact the person, wherein the flexible sheeted thermally conductive material is configured to have air flow through the flexible sheeted thermally conductive material to be conditioned by passing through openings in the flexible sheeted thermally conductive material, whereby both conductive cooling or heating to the surface configured to contact the person and convective cooling or heating via moving conditioned air is provided.
 21. The heating and cooling device of claim 20, wherein said heating and cooling source comprises a thermoelectric device.
 22. The heating and cooling device of claim 21, wherein said thermoelectric device is a bismuth telluride thermoelectric device.
 23. The heating and cooling device of claim 22, wherein the thermoelectric device is a 127 or higher count couple bismuth telluride based device.
 24. The heating and cooling device of claim 20, wherein said heating and cooling source is configured to operate at a voltage ranging from 10 to 16 VDC or from a wireless power source transmitted to a magnetic resonance receiver from a magnetic resonance transmitter for wireless recharging.
 25. The heating and cooling device of claim 20, wherein the flexible sheeted thermally conductive material includes thermally conductive materials comprising at least one of thermally conductive flexible sheeted graphene materials, polymers, or carbon based conductive materials including carbon fiber fabric and graphite fabrics.
 26. The heating and cooling device of claim 20, wherein the flexible sheeted thermally conductive material includes graphene sheets, strips and slitted thermally conductive material strips in thermal communication with each other.
 27. The heating and cooling device of claim 20, wherein the flexible sheeted thermally conductive material comprises a layer of sheets or strips made of a graphene material including graphene nanoplatelets, graphene nanotubes, graphene nanoparticles and combinations thereof.
 28. The heating and cooling device of claim 20, further comprising a thermally conductive interface for creating a thermal connection between the heating and cooling source and the flexible sheeted thermally conductive material, wherein the thermally conductive interface comprises at least one of thermal greases, silver filled gels, filled waxes, silicones, or pads, and wherein the thermally conductive interface is configured to be bonded to aplastic sheet for strength.
 29. The heating and cooling device of claim 20, further comprising a thermally conductive interface for creating a thermal connection between the heating and cooling source and the flexible sheeted thermally conductive material, wherein the thermally conductive interface includes a reworkable, aluminum nitride filled, electrically insulating and thermally conductive paste type epoxy adhesive.
 30. The heating and cooling device of claim 20, wherein heat storage capabilities of the phase change material can be achieved through solid-solid, solid-liquid, solid-gas, or liquid-gas phase change.
 31. The heating and cooling device of claim 20, wherein the phase change material comprises at least one of hydrated potassium bicarbonate, sodium acetate, paraffin, fatty acids, inorganic salt hydrates, eutectics, hydro scopic s, or hygroscopics.
 32. The heating and cooling device of claim 20, further comprising a variable insulating layer between the flexible sheeted thermally conductive material and the phase change material to act as an active thermal gate for heat transfer to and from the phase change material.
 33. The heating and cooling device of claim 32, wherein said variable insulating layer includes a thermally conductive foam layer comprising at least one of polyurethane, other polymeric material, cotton, synthetic fabric material, fiberglass, polyisocyanate foam, or natural batting material.
 34. A heating and cooling device for heating or cooling a surface utilizing a sheeted thermally conductive material within a garment for contacting a person, comprising: a heating and cooling source for generating heat or coolness, said heating and cooling source adapted to be located within the garment; and a flexible sheeted thermally conductive material adapted to be located within the garment and in thermal communication with the heating and cooling source, including a thermally conductive material for distributing heat and coolness generated by the heating and cooling source across a wider area of the garment than the surface of the heating and cooling source itself, said flexible sheeted thermally conductive material being secured to and in thermal contact with the heating and cooling source, and wherein said flexible sheeted thermally conductive material has a thermal conductivity of from 375 to 4000 W/mK for distributing the heat and coolness across the surface of the garment, said thermally conductive material configured to distribute heat and coolness generated by the heating and cooling source across a wider area than the surface of the heating and cooling source itself; and wherein said flexible sheeted thermally conductive material comprises a strip of flexible sheeted material for extending the heat or coolness across the garment by spreading the heat or coolness over a wider distribution area than the surface of the heating and cooling source, wherein the flexible sheeted thermally conductive material is configured to have air flow through the flexible sheeted thermally conductive material to be conditioned by passing through openings in the flexible sheeted thermally conductive material, whereby both conductive cooling or heating to the garment for contacting the person and convective cooling or heating via moving conditioned air is provided.
 35. The heating and cooling device of claim 34, further comprising a superhydrophobic surface material layer to repel water droplets from the surface of the garment by self-propelled jumping condensate powered by surface energy upon coalescence of condensed water phase.
 36. The heating and cooling device of claim 34, further comprising a temperature sensor in electrical communication with the heating and cooling source, wherein the heating and cooling is configured to be turned on or off based on a temperature signal from the temperature sensor, wherein said temperature sensor is configured to be powered by electrical energy produced via Seebeck effect.
 37. The heating and cooling device of claim 34, wherein said heating and cooling source comprises a thermoelectric device.
 38. The heating and cooling device of claim 37, wherein said thermoelectric device is a bismuth telluride thermoelectric device.
 39. The heating and cooling device of claim 37, wherein the thermoelectric device is a 127 or higher count couple bismuth telluride based device.
 40. The heating and cooling device of claim 34, wherein said heating and cooling source is configured to operate at a voltage ranging from 10 to 16 VDC or from a wireless power source transmitted to a magnetic resonance receiver from a magnetic resonance transmitter for wireless recharging.
 41. The heating and cooling device of claim 34, wherein the flexible sheeted thermally conductive material includes thermally conductive materials comprising at least one of thermally conductive flexible sheeted graphene materials, polymers, or carbon based conductive materials including carbon fiber fabric and graphite fabrics.
 42. The heating and cooling device of claim 34, wherein the flexible sheeted thermally conductive material includes graphene sheets, strips and slitted thermally conductive material strips in thermal communication with each other.
 43. The heating and cooling device of claim 34, wherein the flexible sheeted thermally conductive material comprises a layer of sheets or strips made of a graphene material including graphene nanoplatelets, graphene nanotubes, graphene nanoparticles and combinations thereof.
 44. A heating and cooling device with a sheeted thermally conductive material for heating or cooling a surface of a seat, comprising: a heating and cooling source, including a thermoelectric device for generating heat or coolness, said heating and cooling source being adapted for location within the seat; and a flexible sheeted thermally conductive material, said flexible sheeted thermally conductive material configured to distribute heat and coolness generated by the thermoelectric device across a wider area than the surface of the thermoelectric device itself, and also being located within the seat and in thermal communication with said heating and cooling source, including a sheeted thermally conductive material configured to distribute heat or coolness generated by the thermoelectric device, said distribution being across an area extending beyond and outside to a wider area of the seat than the surface of the thermoelectric device itself, said flexible sheeted thermally conductive material being secured to and in thermal contact with the thermoelectric device and configured to conductively heat or cool the surface of the seat, and wherein said flexible sheeted thermally conductive material has a thermal conductivity of from 375 to 4000 W/mK for distributing the heat and coolness across the surface of the seat; said flexible sheeted thermally conductive material comprising a strip of flexible sheeted material that is thermally conductive for distributing the heat or coolness from the thermoelectric device across the surface of the seat, wherein the flexible sheeted thermally conductive material is configured to have air flow through the flexible sheeted thermally conductive material by passing through openings in the flexible sheeted thermally conductive material.
 45. The heating and cooling device of claim 44, further comprising an electronic communication by Internet of Things (IoT) to determine whether the seat is occupied.
 46. The heating and cooling device of claim 44, wherein the flexible sheeted thermally conductive material includes thermally conductive materials comprising at least one of thermally conductive flexible sheeted graphene materials, polymers, or carbon based conductive materials including carbon fiber fabric and graphite fabrics.
 47. The heating and cooling device of claim 44, wherein the sheeted thermally conductive material includes graphene sheets, strips and slitted thermally conductive material strips in thermal communication with each other.
 48. The heating and cooling device of claim 44, wherein the flexible sheeted thermally conductive material comprises a layer of sheets or strips made of a graphene material including graphene nanoplatelets, graphene nanotubes, graphene nanoparticles and combinations thereof.
 49. A heating and cooling device with a sheeted thermally conductive material for heating or cooling a surface in an automobile, comprising: a heating and cooling source, including a thermoelectric device for generating heat or coolness, said thermoelectric device being adapted for location in an automobile; and a flexible sheeted thermally conductive material, said thermally conductive material configured to distribute heat and coolness generated by the thermoelectric device across a wider area than the surface of the thermoelectric device itself, and also being located in the automobile and in thermal communication with said heating and cooling source, including a sheeted thermally conductive material configured to distribute of heat and coolness generated by the thermoelectric device, said distribution being across an area extending beyond and outside of the surface of the thermoelectric device itself, said flexible sheeted thermally conductive material being secured to and in thermal contact with the thermoelectric device and configured to conductively heat or cool the surface in the automobile, and; said flexible sheeted thermally conductive material comprising a strip of flexible sheeted material that is thermally conductive for distributing the heat or coolness from the thermoelectric device across the surface in the automobile, wherein the flexible sheeted thermally conductive material is configured to have air flow through one or more perforations in the flexible sheeted thermally conductive material.
 50. The heating and cooling device of claim 49, further comprising a temperature sensor in electrical communication with the heating and cooling source, wherein the heating and cooling is configured to be turned on or off based on a temperature signal from the temperature sensor, wherein said temperature sensor is configured to be powered by electrical energy produced via Seebeck effect.
 51. The heating and cooling device of claim 49, wherein the flexible sheeted thermally conductive material is configured to have air flow through the flexible sheeted material to be conditioned by passing through openings in the flexible sheeted material, whereby both conductive cooling or heating to the surface in the automobile and convective cooling or heating via moving conditioned air is provided.
 52. A heating and cooling system having a sheeted thermally conductive material for distributing heat or coolness across a surface configured to contact a person, the system comprising: a heating and cooling source for generating heat or coolness; a flexible sheeted thermally conductive material in thermal communication with the heating and cooling source, the flexible sheeted thermally conductive material configured to distribute heat or coolness generated by the heating and cooling source over a distribution area across the surface configured to contact the person that is larger than a surface of the heating and cooling device itself; and a fan configured to move air through one or more perforations in the surface toward the person, wherein the flexible sheeted thermally conductive material comprises one or more perforations, and wherein the fan is configured to move air through the one or more perforations in the flexible sheeted thermally conductive material.
 53. The system of claim 52, wherein the flexible sheeted thermally conductive material comprises graphene.
 54. The system of claim 52, wherein the flexible sheeted thermally conductive material comprises strips of material.
 55. The system of claim 52, wherein the fan is configured to move air through one or more passages in a seat to move air through the one or more perforations in the surface configured to contact the person and the one or more perforations in the flexible sheeted thermally conductive material, the seat comprising the surface configured to contact the person.
 56. The system of claim 52, wherein the heating and cooling source is in thermal communication with a heat sink, and wherein the fan is configured to move air through the heat sink.
 57. The system of claim 56, wherein the fan is configured to move air through the heat sink and away from the surface of the seat via one or more air chambers in the seat.
 58. The system of claim 57, wherein the one or more air chambers are formed in foam of the seat.
 59. The system of claim 57, wherein the fan is configured to move air through a splitting chamber configured to direct air through the one or more perforations in the seat and through the one or more air chambers in the seat.
 60. The system of claim 52, wherein the fan is configured to move air through the one or more perforations in the seat such that the moved air exchanges heat with a phase change material located in the seat, the phase change material configured to store or release heat.
 61. The system of claim 52, wherein the heating and cooling source comprises a thermoelectric device.
 62. The system of claim 61, wherein the thermoelectric device is configured to produce electrical energy via the Seebeck effect with a temperature difference between two planar sides of the thermoelectric device, wherein a temperature sensor is configured to be powered by utilizing electrical energy produced via the Seebeck effect, wherein temperature information from the temperature sensor can be related to the temperature of the person used for controlling the temperature of the surface configured to contact the person and aid in turning on or off or modulating the heat supplied to or the heat removed from the surface configured to contact the person.
 63. The system of claim 52, wherein the heating and cooling source is in thermal communication with the flexible sheeted thermally conductive material via a heat transfer block configured to distribute heat or coolness generated by the heating and cooling source.
 64. The system of claim 52, wherein the heating and cooling source is in thermal communication with the flexible sheeted thermally conductive material via a thermal interface. 